A method and system for forming a packaged product (100) and ensuring that the packaged product (100) is adequately filled. In one aspect, the method includes forming a product (101); introducing the product (101) into a package (103), thereby forming a packaged product (100); obtaining an x-ray image (201) of the packaged product (100); analyzing the x-ray image (201) utilizing a processor (118) to identify whether bounded contours (200) exist in the x-ray image (201) for each of the bounded contours (200), the processor (118) determining whether the bounded contour (200) is a threshold defect based at least in part on bounded area (208) of the bounded contour (200) for each of the threshold defects, the processor (118) classifying the threshold defect as one of a plurality of pre-determined defect types; and determining a source of at least one of the threshold defects in the packaged product (100) based at least in part on the classification of the at least one of the threshold defects.

A bulk HPP container (10) includes a flexible body portion (12) having closed off ends (14), at least one of which is depicted as being recessed to enable the containers (10) to be positioned end-to-end in an efficient manner, for example, when placed into an HPP pressure vessel, such as a wire wound vessel. One or more openings are provided in the body portion of the container with n appropriate closure for pumpable product to enter and exit the container. In this regard, an inlet valve (16) or other type of closure may be located at the opening in one or both of the ends of the container. Also, one or more outlet valves (18) or other type of closure are located at an opening on the body portion (12) of the container for emptying the container, for example, after HPP. The body portion 12) is composed of sufficient flexural strength and sufficient flexural modulus to enable the container to reduce in volume by from 0 to at least 30% while being rigid enough for reuse over a desired number of HPP cycles.

A defrosting apparatus has a foundation unit having a top surface and sidewalls, housing an electrically-powered water pump with an inlet and an outlet, with an opening in a sidewall enabling water to pass from outside the foundation unit to inside, a vertically oriented conduit extending from the top surface of the foundation unit, with a lower end connected to the outlet of the water pump, and an upper end, a horizontally-oriented conduit having a first and a second end, connected proximate the first end to the upper end of the vertically-oriented conduit, a vertically-oriented downspout connected at the second end of the horizontally-oriented, telescoping conduit assembly, the downspout open at a lower end, and a control unit comprising a CPU, a digital memory and wireless communication circuitry, the control unit coupled to a temperature sensor in contact with the flowing water, and to pump control inputs.

Disclosed are various embodiments for a decontamination tank and method for treating reducing microbial contamination of a food product. In one embodiment, decontamination tank comprises a first chamber for holding a first antimicrobial bearing liquid for reducing a microbial contamination on a surface of the food product. The decontamination tank further comprises a second chamber for holding a second antimicrobial bearing liquid of different content than the first antimicrobial bearing liquid in the first chamber, for further reducing the microbial contamination on the surface of the food product. The decontamination tank further comprises a first unloader configured to remove the food product from the first antimicrobial bearing liquid in the first chamber and to deposit the food product toward the second chamber. The decontamination tank further comprises a second unloader configured to remove the food product from the second antimicrobial bearing liquid in the second chamber.

Disclosed is a method of producing brewed, matured or fermented food, comprising: exposing the food to sound having a frequency of higher than 1 Hz and less than 400 Hz during brewing, maturation or fermentation. The method enables improved efficiency with respect to the yield of desirable flavors and flavor development control and ideally also prolonged shelf-life. Also disclosed are systems for performing said method and food products produced by said method.

The present invention relates to an air-drying plant for air drying cut-up food. The proposed plant consists of a conveyor (10) for cut-up food (1) defining a conveying surface (11), a plurality of blowing conduits (20) with blowing openings (21) channeling a treated airflow at a speed of treatment with a controlled temperature comprised between 4° C. and 60° C. and a controlled humidity; wherein the conveyor includes air treatment segments (12) with conveying surfaces (11) facing and adjacent to said blowing openings (21), said treated airflow being channeled against said conveying surface (11) in an upward or downward direction; and wherein the conveyor (10) also includes idle segments (13) intercalated between said air treatment segments (12), the conveying surface (11) of which is not facing the blowing openings (21), nor is it subjected to an airflow.

A container (1) for storage of solids, discrete elements, granular materials or liquid, comprises a base (2) and a lid (3) and the base (2) are suitable for forming an air tight storage volume (23). The base (2) and lid (3) comprise respective base closing devices (24) and lid closing devices (34) arranged to cooperate to close the container (1) and limit relative movement between the base (2) and the lid (3) by the closing devices (24, 34). The lid (3) has an lid base (33) and an adaptation device (35) arranged between the lid closing devices (34) and the inner part of the lid (33). The adaptation device (35) is placed to push the lid base (33) from the lid closing device (34) toward a bottom (21) of the base (2) for adaptation of the storage volume (23) to the content (4) in the container (1).

A container (1) for storage of solids, discrete elements, granular materials or liquid, comprises a base (2) and a lid (3) and the base (2) are suitable for forming an air tight storage volume (23). The base (2) and lid (3) comprise respective base closing devices (24) and lid closing devices (34) arranged to cooperate to close the container (1) and limit relative movement between the base (2) and the lid (3) by the closing devices (24, 34). The lid (3) has an lid base (33) and an adaptation device (35) arranged between the lid closing devices (34) and the inner part of the lid (33). The adaptation device (35) is placed to push the lid base (33) from the lid closing device (34) toward a bottom (21) of the base (2) for adaptation of the storage volume (23) to the content (4) in the container (1).

Embodiments of the present disclosure provide an auger dip apparatus for the application of antimicrobial solution to raw food. Embodiments of the present disclosure may use an auger as a single moving part to move the food work pieces through the application area for antimicrobial solution. Embodiments of the present disclosure are simple with only one moving auger part to move the food pieces, and the bearing for the moving part, supporting the shaft of the auger, may be configured to be outside of the cabinet with the reservoir of the antimicrobial solution, so that the bearing is not in contact with the antimicrobial solution. This provides for less maintenance and downtime, particularly unscheduled downtime, than a system using more complicated exposed parts. The present disclosure also permits a more compact and lighter configuration for an assembled application unit.

A food ingredient transfer device is provided. The food ingredient transfer device includes a dosing device configured to receive a food ingredient, and a first chamber that is provided with an inlet and an outlet for allowing the dosing device to pass through the first chamber. The food ingredient transfer device further includes a second chamber arranged adjacent to the first chamber for receiving the dosing device when it has passed through the first chamber, the second chamber being provided with an outlet for allowing the dosing device to pass through the second chamber and into an enclosure that contains a food product to which the food ingredient shall be transferred.